Method for manufacturing a magnetic hard disk having concentric magnetic tracks with flat surface

ABSTRACT

A magnetic hard disk having magnetic tracks for storing data which is read or written by a magnetic head floating immediately above the magnetic track while the magnetic hard disk is rotating, and the magnetic head rests on the magnetic hard disk while the magnetic hard disk is not rotating. One aspect of the present invention is that the magnetic hard disk comprises a non-magnetic substrate having a plurality of banks and grooves alternately and concentrically arranged thereon, a magnetic film formed on each of the banks, and non-magnetic material formed on an entire surface of the substrate all over the banks and grooves such that roughness of the upper surface of the non-magnetic material is in a range between 0.5 nm and 3 nm.

This is a divisional of application Ser. No. 09/468,962, filed Dec. 22, 1999.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based upon and claims priority of Japanese Patent Application No. Hei 10-374594, filed the contents being incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a magnetic hard disk capable of writing and reading magnetic data thereon, and more particularly, to a magnetic hard disk having concentric magnetic tracks spaced to each other on a non-magnetic substrate, and a fabrication method thereof.

2. Description of the Related Art

As the infrastructure of information and communication in the society is progressed, a magnetic hard disk driver (or HDD) as an external memory of computers rises in importance increasingly, and its storage density increases rapidly year by year. Tendency for seeking smaller size and larger volume in the memory demands narrower magnetic tracks and higher storage density for the magnetic hard disk.

Since storage density of the magnetic hard disk depends upon both of linear density along a track and track density in the radial direction, improvement of either one or both results in higher storage density of the magnetic hard disk. The present invention is directed to an improvement of a technology related to the track density.

In general, auxiliary data is initially recorded on a magnetic hard disk, which is information necessary for writing or reading data on the magnetic hard disk, such as servo data (or tracking servo data) for positioning a magnetic head on a track, address data for registering a position of written data and PLL lock data for reading out address data. To increase the track density, simply narrowing a space between tracks results in a serious problem under a circumstance that a track is generated by writing data by a magnetic head as in conventional manner. FIG. 1A is a partial cross-sectional view of a typical conventional magnetic hard disk having a continuous magnetic film, in which the magnetic disk consists of a flat substrate 1 and successively laminated three thin films of chromium 2, cobalt-chromium-platinum-tantalum alloy 3, and amorphous carbon 4. When narrow-pitched magnetic tracks are written on a continuous magnetic film by simply narrowing a spacing between magnetic head trajectories of the nearest neighbors, a stray magnetic field coming out laterally from both sides of the magnetic head magnetizes a guard band between tracks which resultantly causes magnetic noises. Narrowing track width also gives rise to decrease of a signal to noise ratio (or S/N) problem at reading out a written data. The similar problem occurs in recording of tracking servo data for controlling a position of a magnetic head. As narrowing the track width, it becomes increasingly difficult to obtain a highly accurate servo data. To maintain the S/N ratio for narrower track width, it has been proposed to form various physical features such as bumps or grooves on a surface of a disk substrate by which servo signal or position of a track is determined. (for instance, a Japanese Laid Open Patent Application H3-252922). According to this technique, a servo mark is formed on the magnetic disk for tracking a magnetic head by which the magnetic head can be controlled to follow a magnetic track with high accuracy. The servo mark is written by servo writer. Narrowing track width for higher track density requires higher accuracy in positioning the servo mark, which further needs higher positioning accuracy between a servo writer and a HDD. Therefore, a drawback of this approach is requirement for higher technical accuracy to the positioning device which incurs extra cost. To overcome this drawback, it has been proposed to pre-form the servo mark by which accuracy in positioning the servo mark can be increased. Several methods for pre-forming the servo mark are disclosed, for instance, by etching a magnetic film as in Japanese Laid Open Patent Applications S62-256225 and H1-23418, or by forming bumps and grooves on a disk substrate as in H8-17155. FIG. 1B is a partial cross-sectional view of another typical conventional magnetic hard disk having a partially refilled groove between magnetic tracks neighboring to each other, in which the magnetic disk consists of a flat substrate 1 and successively laminated three thin films of chromium 2, cobalt-chromium-platinum-tantalum alloy 3, and amorphous carbon 4, as same as FIG. 1A except that there are partially refilled grooves 7 between pre-determined tracks 8.

However, a drawback of these methods is to leave surface roughness from several tens nanometers to several hundreds nanometers in overall height on the magnetic disk. Since floating stability of a magnetic head, which means how stably a magnetic head can maintain a predetermined distance from the rotating magnetic disk, for a magnetic disk of high track density in a conventional HDD can be attained by flattening and smoothing the surface of a magnetic disk, and since decrease of the distance between a floating magnetic head and a magnetic disk is also needed to operate a magnetic disk having higher density maintaining the appropriate S/N ratio, the both approaches clearly conflicts with these technical requirements.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a magnetic hard disk having a plurality of concentrically disposed magnetic tracks with high radial density, which maintains sufficiently long durability of a non-contact magnetic head floating immediately above the magnetic tracks, the magnetic hard disk comprising a non-magnetic substrate having an upper surface with a concentrically patterned magnetic film thereon, and a non-magnetic protecting film on the entire upper surface of the magnetic hard disk, wherein roughness of the upper surface of the non-magnetic protecting film is in a range between 0.5 nm and 3 nm.

Another object of the present invention is to provide a magnetic hard disk having high radial density of magnetic tracks without degrading signal to noise ratio. According to one aspect of the invention, a magnetic hard disk comprises a non-magnetic substrate having alternately disposed concentric banks and grooves on the upper surface, a magnetic film on each of the concentric banks, and a non-magnetic film covering the magnetic film and refilling the grooves such that the upper surface of the non-magnetic film has the same surface roughness and continuity across the banks and grooves.

Further object of the present invention is to provide a reliable method for fabricating the magnetic hard disk having high radial density of magnetic tracks, the method comprise the steps of forming alternately disposed concentric banks and grooves on a non-magnetic substrate, forming a magnetic film and a first non-magnetic film on each of the concentric banks, successively forming a second non-magnetic film on an entire surface of the magnetic hard disk so as to cover the first non-magnetic film and refill the grooves therewith, removing the second non-magnetic film from the upper surface of the first non-magnetic film by Damascene method until the first non-magnetic film is exposed, and subsequently forming a third non-magnetic film on an entire surface of the magnetic hard disk and finally roughening the upper surface of the third non-magnetic film such that roughness of the upper surface of the third non-magnetic film falls in a range between 0.5 nm and 3 nm.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be more apparent from the following description, when taken to conjunction with the accompanying drawings, in which:

FIG. 1A is a partial cross-sectional view of a prior art magnetic hard disk having a continuous magnetic film.

FIG. 1B is a partial cross-sectional view of a prior art magnetic hard disk having a groove between concentric tracks.

FIG. 2 is an instrument for the acoustic emission measurement.

FIG. 3 is a partial cross-sectional view of a magnetic hard disk having a continuous magnetic film for magnetic head stability test.

FIG. 4 is a graph of relationship between an output voltage of the acoustic emission (or AE) sensor and duration time on the magnetic hard disk shown in FIG. 3.

FIG. 5 is a partial cross-sectional view of a magnetic hard disk having a groove between concentric tracks for magnetic head stability test.

FIG. 6 is a graph of relationship between an output voltage of the AE sensor and duration time on the magnetic hard disks with various groove depths.

FIG. 7 is a graph of relationship between static friction and surface roughness of magnetic hard disks by CSS durability test.

FIG. 8 is a graph of relationship between an AE sensor output and surface roughness of magnetic hard disks by floating durability test.

FIGS. 9A, 9B and 9C are partial cross-sectional views of a magnetic hard disk in various fabrication processing steps for the first embodiment according to the present invention.

FIG. 10 is a graph of relationship between output voltages of an AE sensor and duration time on magnetic hard disks having protective films of a-carbon and DLC.

FIG. 11 is a graph of relationship between output voltages of an AE sensor and duration time on magnetic hard disks having protective films of Al2O3 and SiO2.

FIGS. 12A and 12B are partial cross-sectional views of a magnetic hard disk before and after planarization processes, respectively, for the second through fourth embodiments according to the present invention.

FIGS. 13A, 13B, 13C and 13D are partial cross-sectional views of a magnetic hard disk in various fabrication processing steps for the fifth embodiment according to the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Thus, the inventors investigated the floating stability of a magnetic head in terms of surface roughness of a magnetic hard disk in more detail. The floating stability of a magnetic head can be evaluated by an output voltage of an acoustic emission sensor installed on the magnetic head which detects a dynamic contact of the magnetic head against the surface of the magnetic hard disk during rotating the magnetic disk. FIG. 2 shows an instrument for the acoustic emission measurement, which mainly consists of a stage 11, air-spindle rotator 12, a magnetic hard disk 13, a magnetic head 14, an acoustic emission sensor 15, amplifier/band-path filter circuit 16 and output terminal 17. When the magnetic hard disk 13 is rotated at a constant track-speed of 12 meters per second for measurements, the magnetic head 14 is lifted off by 25 nm above the disk surface. FIG. 3 shows a cross-sectional view of a magnetic hard disk having a flat surface with no grooves as a control, in which the magnetic hard disk consists of a flat substrate 1 and successively laminated three thin films of 20 nm-thick chromium 2, 20 nm-thick cobalt-chromium-platinum-tantalum alloy 3, and 20 nm-thick amorphous carbon 4. FIG. 4 shows an experimental result of the magnetic hard disk having a flat surface with no grooves. The result indicates that the output voltage of the acoustic emission sensor versus time is unchanged for more than 1000 hours. It was also confirmed that the floating stability was maintained for more than 1000 hours during continuous operation with a currently commercially available magnetic hard disk having grooves as far as the floating distances of the magnetic head are 50 nm and 100 nm. On the other hand, when the floating distances of the magnetic head were changed to be 30, 25 and 20 nm, the crashes occurred within 50, 5 and 3 hours, respectively. FIG. 5 shows a cross-sectional view of magnetic hard disks having concentric grooves of 30 nm, 60 nm, and 90 nm in depth with 0.3 nm in width and 3.0 nm in pitch. FIG. 6 shows an experimental result of the magnetic disks having different groove depths. Although there was some difference in durability between the magnetic hard disks having different depths of the groove, all of them started increasing in an output of the acoustic emission (or AE) sensor within 4 hours and that crashed to the disk within about 30 minutes after the respective steep increases of the output. The result of all durability tests of the floating magnetic head by continuous operation are tabulated in Table 1, together with the conventional magnetic hard disks.

TABLE 1 Groove Depth Floating No. (nm) Distance (nm) Life (hour) Notes 1 30 20 less than 3 2 30 25 less than 3 FIG. 6 3 60 25 less than 4 FIG. 6 4 90 25 less than 4.5 FIG. 6 5 30 25 less than 5 6 0 25 more than 1000 FIG. 4 7 30 30 less than 50 8 0 50 more than 1000 Prior Art 9 30 50 more than 1000 Prior Art 10 30 100 more than 1000

It can be concluded from these experiments that it becomes more difficult to maintain sufficient stability of the floating head as a distance between the floating head and the surface of the grooved magnetic hard disks becomes smaller.

On the other hand, a magnetic head is usually rested on the surface of a magnetic disk when the device is not operated. As the disk starts rotating, the magnetic head is lifted off from the surface of a magnetic disk by air-flow. This type of operating method is called a “contact start and stop” (or CSS) method. It is known that in the CSS method, a magnetic head often does not leave promptly from the contact surface of the disk when the disk starts rotating because the head clings to the contact surface. This effect results in instability of the magnetic head or even permanent damage of the magnetic head. Thus, another series of experiments were carried out to study an effect of surface roughness of protective films on the instability due to the CSS method. Protective films having various surface roughness and materials were prepared to measure the coefficient of static friction and an AE sensor output for floating stabilities of static and dynamic states, respectively. Samples for the measurements have substantially the same structure as that shown in FIG. 3. Various textured surfaces were provided by polishing the surface with polishing powder having different sizes. FIG. 7 shows a relationship between the coefficient of static friction and surface roughness obtained by the CSS method. The graph indicates that the coefficient of static friction increased rapidly as the surface roughness decreased below 0.5 nm, in which the surface roughness is measured by a height from an averaged center line as defined by Japanese Industrial Standard (or JIS) B 0601-1982, unless otherwise referred to. Further, the crash occurred after roughly 500 time-repetition of stop and start operation under contact condition at an average surface roughness of 0.2 nm. In contrast, no crash occurred after more than 1000 time-repetition test at an average surface roughness of greater than 0.5 nm. FIG. 8 shows a relationship between an output voltage of an AE sensor and surface roughness. The graph in FIG. 8 indicates that the output voltage of an AE sensor increased rapidly beyond an average surface roughness of greater than 3 nm. The crash occurred within 50 hours at an average surface roughness of 4.7 nm. While no crash occurred for more than 1000 hours for dynamic floating durability test at an average surface roughness of smaller than 3 nm.

Thus, flatness and roughness of the surface of a magnetic hard disk should be precisely selected to fulfill the foregoing technical requirements for an advanced magnetic hard disk having high density magnetic tracks.

Embodiment 1

FIGS. 9A, 9B and 9C are partial cross-sectional views of a magnetic disk in various fabrication processing steps for the first embodiment of the present invention.

A disk substrate 1 is made of non-magnetic material such as aluminum, aluminum alloy, ceramics, glass or plastics, or antiferro-magnetic material such as MnO, Cr₂O₃, FeS, FeCl₂ or MnAs. Further, a surface of the disk substrate 1 may be coated by an aluminum oxide film, electroplating metal films or alike to obtain better flatness and anti-corrosion. Concentric grooves 7 are formed on the surface of the disk substrate 1 leaving concentric banks 8 alternately to each other by photolithography and anisotropic etching. FIG. 9A is a partial radial cross-sectional view of a disk substrate 1. A magnetic film 3 is formed on the surface of the banks by depositing magnetic material in a normal direction to the surface of the disk substrate by which the magnetic film may be deposited on the bottom of the grooves but not on the side wall. Each of the magnetic films on the surface of the banks must be separated from the nearest magnetic film on the surface of the banks and bottoms so as to neglect magnetic interference between them. A non-magnetic film 4 is successively deposited over the entire surface of the disk substrate such that the non-magnetic film 4 is thick enough to refill the grooves as shown in FIG. 9B. Subsequently, the non-magnetic film 4 is polished precisely until a thin protective film, such as 20 nm thick, on the magnetic film 3 on each of the banks 8 is left and surface roughness is in a range of 0.5 nm to 3 nm as shown in FIG. 9C. The magnetic disk of this structure simultaneously satisfies both requirements for surface roughness of the upper surface for the stabilities of static and dynamic states and complete separation between neighboring magnetic tracks.

Embodiment 2

FIG. 12A is a partial cross-sectional view of a magnetic hard disk before planarization for the second embodiment according to the present invention.

Concentric grooves were formed on the surface of a glass substrate 1 of 3.5 inch diameter. Width of a track was 2.7 μm wide. Width and depth of the groove were 0.3 μm wide and 50 nm deep, respectively. A 20 nm thick underlay of Chromium film 2, a 20 nm thick magnetic film 3 of Cobalt-Chromium-Platinum-Tantalum alloy, a 20 nm thick Chromium film 4 of the first non-magnetic film were successively deposited on the grooved substrate by sputtering method, and subsequently a 80 nm thick SiO2 film 5 of the second non-magnetic film was deposited by either sputtering or CVD method until the groove was completely refilled as shown in FIG. 12A.

FIG. 12B is a partial cross-sectional view of a magnetic hard disk after planarization for the second embodiment according to the present invention.

The SiO2 film 5 was planarized by chemical mechanical polishing (or CMP) method until the Chromium film 4 was exposed. Detailed condition of the CMP method was as follows:

Polishing agent was KOH solution added colloidal silica slurry (about 20 μm in diameter ) diluted with water until the volume reached ten times larger than that of the slurry. Polisher was polyurethane cloth. Load was 2.6 kgf. Revolution speed of a stage was 50 rpm. The planarization process is not only limited to the CMP method but also an etch-back method widely used in semiconductor wafer fabrication is feasible.

After planarization, a 10 nm thick amorphous carbon (or a-carbon) film 6 as the third non-magnetic film was deposited all over the polished surface. The a-carbon film acts as a protective film for an anti-corrosion and anti-wearing purposes. This a-carbon film had surface roughness of 0.83 nm. In the Embodiment 1, the disk substrate can be replaced by poly-carbonate (PC), amorphous poly-olefin (a-PO), or poly-methyl-metacrylate (PMMA) substrate. The other conditions being equal, the third non-magnetic films for these replaced disk substrates had the surface roughness of 0.91 nm, 0.88 nm, and 0.90 nm, respectively.

Embodiment 3

Two different samples were prepared, wherein one of the disk substrate was glass and another was poly-carbonate. The first and second non-magnetic films of both cases were selected to be a 10 nm thick a-carbon and a 10 nm thick Chromium film, and the other conditions were equal to those in the Embodiment 2. All cases of Embodiments 2 and 3 with surface roughness from 0.5 nm to 3 nm satisfied the both requirements for dynamic and CSS durability tests.

Embodiment 4

To know the effect of materials of the protective film, the third non-magnetic film in Embodiment 2, on the floating characteristics of the magnetic head, two groups of samples having different materials for the protective non-magnetic film 4 were formed directly on disk substrates having a flat and smooth surface, the disk substrates are made of glass and PC. The protective non-magnetic films of the first and second groups were a-carbon and diamond-like carbon (DLC), and Al2O3 and SiO2, respectively. Both samples of the first group showed stable operations for more than 1000 hours as shown in FIG. 10, while both samples of the second group crashed within 100 to 200 hours as shown in FIG. 11. These results suggest that hardness of the protective (or third) non-magnetic film must be higher than that of Al2O3 or SiO2 film. Silicon nitride (Si3N4) is another prospective material for the protective (or third) non-magnetic film. All experimental results on floating durability are summarized in Table 2.

TABLE 2 1'st non- 2'nd non- surface Floating magnetic magnetic Protective roughness durability No. substrate film film film (nm) (hours) 1 glass Cr SiO2 a-carbon 0.83 more than 1000 2 PC Cr SiO2 a-carbon 0.91 more than 1000 3 a-PO Cr SiO2 a-carbon 0.88 more than 1000 4 PMMA Cr SiO2 a-carbon 0.90 more than 1000 5 glass a-carbon Cr a-carbon 0.94 more than 1000 6 PC a-carbon Cr a-carbon 0.98 more than 1000 7 glass — — a-carbon 0.90 more than 1000 or PC 8 glass — — DLC 0.92 more than 1000 or PC 9 glass a-carbon — — 60   less than 3  (groove depth) 10 PC a-carbon — — 60   less than 4  (groove depth) 11 glass — — Al2O3 1.05 less than 100 or PC 12 glass — — SiO2 1.01 less than 200 or PC

As described above, to ensure stable continuous operation for more than 1000 hours, the surface roughness of the magnetic hard disk should be greater than 0.5 nm for the CSS type operation and smaller than 3.0 nm for a floating head with a floating distance lower than 30 nm. Although it is important that magnetic tracks are magnetically isolated from each other on writing or reading operation, a groove between concentric magnetic tracks is not essential to the present invention.

Embodiment 5

FIGS. 13A through 13D are partial cross-sectional views of a magnetic hard disk in various fabrication processing steps for the fifth embodiment according to the present invention.

Photoresist patterns 9 concentrically arranged around a center of a substrate disk is formed on a flat upper surface of a glass substrate 1, as shown in FIG. 13A. Width and space of the patterns are 0.3 μm wide and 2.7 μm wide, respectively. A 20 nm thick underlay of Chromium film 2, a 20 nm thick magnetic film 3 of Cobalt-Chromium-Platinum-Tantalum alloy, a 20 nm thick Chromium film 4 of the first non-magnetic film are successively deposited on the patterned substrate from the perpendicular direction to the substrate by sputtering method as shown in FIG. 13B. The photoresist patterns 9 are removed together with the unnecessary films deposited thereon by lift-off method to leave concentric magnetic tracks on the substrate. Subsequently, a 80 nm thick SiO2 film 5 is deposited uniformly by either sputtering or CVD method until the magnetic tracks and the space therebetween are completely buried as shown in FIG. 13C. The SiO2 film 5 is planarized by CMP method until the Chromium film 4 as a stopper film is exposed so that the planarized surface have surface roughness smaller than 3 nm. A 10 nm thick a-carbon film 6 is deposited all over the polished surface as shown in FIG. 13D. Finally, the surface is roughened by another polishing so that the final surface has roughness greater than 0.5 nm maintaining the surface roughness smaller than 3 nm inherited from the surface roughness of the underlaid SiO2 film. 

What is claimed is:
 1. A method for fabricating a magnetic hard disk rotatable around a center of the disk having a plurality of magnetic tracks concentrically disposed around the center of the disk and spaced to each other, comprising the steps of: forming a first non-magnetic film on an upper surface of a substrate made of non-magnetic or antiferro-magnetic material; forming a magnetic film concentrically patterned around the center of said substrate on an upper surface of said first non-magnetic film to form the magnetic tracks; forming a second non-magnetic film on said magnetic film; forming a third non-magnetic film continuously on said second non-magnetic film and a space between each pair of said magnetic tracks adjacent to each other such that an upper surface of said third non-magnetic film exceeds a plane of the upper surface of said second non-magnetic film; removing an upper part of said third non-magnetic film such that both upper surfaces of said second and third non-magnetic films are in a plane parallel to a plane of rotation of the magnetic hard disk; forming a fourth non-magnetic film continuously on both said second and third non-magnetic films; and roughening an upper surface of said fourth non-magnetic film such that the upper surface has surface roughness greater than 0.5 nm maintaining a maximum surface roughness smaller than 3 nm.
 2. A method for fabricating a magnetic hard disk according to claim 1, further comprising the step of: forming a plurality of grooves concentrically disposed around the center of said substrate leaving a bank between each pair of the grooves adjacent to each other on the upper surface of said substrate such that each of the magnetic tracks coincides with the bank in position.
 3. A method for fabricating a magnetic hard disk according to claim 1, wherein the step of removing the upper part of said third non-magnetic film is carried out by chemical mechanical polishing method until the upper surface of said second non-magnetic film is fully exposed.
 4. A method for fabricating a magnetic hard disk according to claim 1, wherein the step of roughening an upper surface of said fourth non-magnetic film is carried out by mechanical polishing method using polishing powder.
 5. A method for fabricating a magnetic hard disk rotatable around a center of the disk having a plurality of magnetic tracks concentrically disposed around the center of the disk and spaced to each other, comprising the steps of: forming photoresist patterns concentrically arranged around a center of a substrate disk on a flat upper surface of a disk substrate such that width and space of the photoresist patterns corresponds to space and width of the magnetic tracks, respectively; depositing a first non-magnetic film, a magnetic film, a second non-magnetic film successively on the disk substrate having the photoresist patterns in the perpendicular direction to the substrate by sputtering method; removing the photoresist patterns together with deposited films thereon by lift-off method such that deposited films on the flat upper surface of the disk substrate are left; depositing a third non-magnetic film isotropically over the disk substrate such that a lowermost portion of an upper surface of the third non-magnetic film exceeds an uppermost portion of an upper surface of the second non-magnetic film; planarizing the third non-magnetic film by chemical mechanical polishing method until the upper surface of the second non-magnetic film is exposed such that the planarized surface has surface roughness smaller than 3 nm; depositing a fourth non-magnetic film all over the planarized surface; and roughening an upper surface of the fourth non-magnetic film by another polishing method such that the upper surface has roughness greater than 0.5 nm maintaining the surface roughness smaller than 3 nm inherited from the surface roughness of the planarized surface. 